DNA turnover and the molecular clock

Abstract

Many detailed studies on the mechanisms by which different components of eukaryotic nuclear genomes have diverged reveal that the majority of sequences are seemingly not passively accumulating base substitutions in a clocklike manner solely determined by laws of diffusion at the population level. It appears that variation in the rates, units, biases, and gradients of several DNA turnover mechanisms are contributing to the course of DNA divergence. Turnover mechanisms have the potential to retard, maintain, or accelerate the rate of DNA differentiation between populations. Furthermore, examples are known of coding and noncoding DNA subject to the simultaneous operation of several turnover mechanisms leading to complex patterns of fine-scale restructuring and divergence, generally uninterpretable using selection and/or neutral drift arguments in isolation. Constancy in the rate of divergence, where observed over defined periods of time, could be a reflection of constancy in the rates and units of turnover. However, a consideration of the generally large disparity between rates of turnover and mutation reveals that DNA clocks, which would be independently driven by turnover in separate genomic components, would tend to be episodic. The utility of any given DNA sequence for measuring time and species relationships, like individual proteins, is proportional to the extent to which all contributing forces to the evolution of the sequence, internal and external, are understood.